CH710563A2 - perpetual calendar. - Google Patents

Abstract

The invention relates to a horological calendar mechanism (700) displaying the duration of the current month and comprising a cam of the perimeter months (9) accessible to a reader probe (301) of a perpetual calendar mechanism. to record the duration of the current month, this calendar mechanism (700) and its cam of the months (9) being updated monthly with each change of current month by the perpetual calendar mechanism. The cam of the months (9) is trivialized for a whole number of years each having a month of February of 28 days, the calendar mechanism (700) comprises a leap mechanism (900) external to the cam of the months (9) and arranged to interpose radially, every four years in February, a first correcting finger (901) between the periphery (90) and the reader probe (301) to give the latter the information that the current month of February has 29 days. The invention also relates to a perpetual calendar mechanism comprising a calendar mechanism (700) according to the invention as well as a watch mechanism and a timepiece.

Description

Field of the invention

The invention relates to a calendar mechanism for perpetual calendar clock mechanism, said calendar mechanism being arranged to display the duration of the current month and having a cam of months whose periphery is accessible to a reader probe. a perpetual calendar mechanism for taking information of the duration of the current month, wherein said calendar mechanism and its so-called month cam are arranged for their monthly update at each change of current month by a said mechanism of perpetual calendar.

The invention also relates to a perpetual calendar watch mechanism comprising such a calendar mechanism and a daily down-counter mechanism which comprises a probe reader of the measurement of the current month's duration and a catch-up mechanism at the end of the month. said probe reader taking the information of the duration of the current month on said periphery of said cam months.

The invention also relates to a watchmaking mechanism comprising a watch movement arranged to control the daily trigger, at the time of the change of date, an actuating mechanism of such a perpetual calendar mechanism, and comprising a display mechanism comprising at least date display means controlled by said calendar mechanism.

The invention also relates to a timepiece comprising such a clockwork mechanism.

The invention relates to the field of date display mechanisms on mechanical watches, and more particularly perpetual calendar.

Background of the invention

The most classic timepieces calendar are described in particular by the treaty "The complicated watches" written by Francois Lecoultre and published by Editions Horloges in Bienne.

[0007] The purpose of a perpetual calendar mechanism is to determine the number of days of the current month and, more particularly, of the current February. The notion of perpetual mechanism is approximate: most trading mechanisms are management mechanisms for simple leap years, either by using a cam of 48-notch months, or a 12-position cam of months, whose February position includes a leap mechanism with a Maltese cross or similar, to quote the best known.

[0008] The very particular management of the secular years, the quadrennecular years, imposed by the Gregorian calendar, makes these applications very rare, only the secular years actually exist on some watches regarded as very high complications. The quadrisecular years and the four-year-olds are only found on astronomical clocks, including that of the Strasbourg Cathedral perfected by Schwilgué in the nineteenth century.

The design of a perpetual calendar mechanism faces two difficulties: taking into account the specificities of the type of calendar that is considered, and its translation into a watch mechanism, and updating such a mechanism in the event of a shutdown. This update is often so complex that the timepiece must never be stopped, as is the case for building astronomical clocks. Even in the case of the most basic version of a perpetual Gregorian calendar with the only management of leap years in four-year cycles, any update results in a large number of manipulations, up to 47 maneuvers for arrive at the right year and the right month, which results in a wear of the mechanisms.

Summary of the invention

The invention proposes to facilitate the correction of a perpetual calendar mechanism, regardless of its level of complexity.

The simple solution, with a reduced number of components, also allows easier realization of a true perpetual calendar, actually integrating the complications of secular years, quadrisecular years or quadrillennial years.

For this purpose, the invention relates to a calendar mechanism for a perpetual calendar watch mechanism, said calendar mechanism being arranged to display the duration of the current month and having a cam months whose periphery is accessible to a probe reader of a perpetual calendar mechanism for taking information of the duration of the current month, wherein said calendar mechanism and its so-called month cam are arranged for their monthly update at each change of current month by a said perpetual calendar mechanism, characterized in that said month cam is trivialized for an integer number of years each having a February month of 28 days, and in that said calendar mechanism comprises a leap mechanism external to said cam months and arranged to interpose radially, every four years in February, a first correction finger between the periphery of said cam months and a so-called reader probe to give the latter the information that the current February has 29 days instead of 28.

The invention also relates to a perpetual calendar watch mechanism comprising such a calendar mechanism and a daily down-time mechanism which comprises a probe reader of the measurement of the current month's duration and a catch-up mechanism at the end of the month. said reader probe taking the information of the duration of the current month on said periphery of said cam of months, characterized in that said daily downward mechanism determines the current day of the month, controls the display of the date, and controls, each change of current month, a movement of said cam months for updating said calendar mechanism, and said leap mechanism which it provides training.

The invention also relates to a watch mechanism comprising a watch movement arranged to control the daily trigger, at the time of the change of date, an actuating mechanism of such a perpetual calendar mechanism, and comprising a display mechanism comprising at least date display means controlled by said calendar mechanism.

The invention also relates to a timepiece comprising such a clockwork mechanism.

Brief description of the drawings

Other features and advantages of the invention will appear on reading the detailed description which follows, with reference to the accompanying drawings, in which: <tb> fig. 1 <SEP> represents, schematically, partially and in top view, a perpetual calendar mechanism according to the invention, in a simplified execution with leap year management, in a position where the mechanism performs a correction which corresponds to a February of 29 days; <tb> fig. 2 <SEP> represents, in view from below, the mechanism of FIG. 1, in the same position; <tb> fig. 3 <SEP> represents, analogously to FIG. 2, the same mechanism, in a position corresponding to a month of February of 28 days, in which the correction mechanism is disengaged; <tb> fig. 4 <SEP> is a side view, in the direction D, of the same mechanism in the position of FIG. 2; <tb> fig. <SEP> represents, similarly to FIG. 4, a perpetual calendar mechanism according to the invention, in a complex execution comprising the management of leap years, secular years, quadrisecular years, and quadrillennial years, according to the Gregorian calendar; <tb> fig. 6 <SEP> represents, in plan view, the mechanism of FIG. 5, each correction element being represented in a position named A where the correction is inactive and a position named B where the correction is active; <tb> fig. 7 <SEP> represents, schematically, partially, and in plan, a variant of the mechanism of FIG. 1; <tb> fig. 8 <SEP> is a block diagram representing a timepiece, in particular a watch, comprising a clockwork mechanism itself comprising a clockwork movement and such a perpetual calendar mechanism.

Detailed Description of the Preferred Embodiments

The invention has a correction mechanism for a calendar mechanism of a perpetual calendar mechanism.

The invention also has a true perpetual calendar mechanism, actually integrating the complications of secular years, quadrisecular years, quadrillennial years, according to the Gregorian calendar.

The invention is described in the preferred application in Europe of the Gregorian calendar. It is nonetheless applicable to any type of calendar that has uneven months from one year to the next.

The present description does not illustrate the entire display mechanism, and is limited to illustrate how to allow a probe finger to read on a mobile exact information as to the duration of the current period. The mobile is here a cam of the months, the current period is a current month. This particular application is not limiting, and the skilled person will be able to transpose it to other types of calendars such as lunar, catch-up periods, or others. The probe finger is also a particular application, which can be replaced by any other control mechanism of the display. The invention is applicable to any calendar display, retrograde or not, instantaneous or not.

As illustrated, the perpetual calendar mechanism comprises components which are essentially cams and levers, the form of which is exposed here is only indicative, and which is essentially imposed by the other complications of the piece and the need to avoid interference, which may lead to more complex forms than their own functions require. Naturally these components can be replaced or supplemented by other components to perform similar functions, including wheels, stars, or other.

Some mobiles schematized here have a very long periodicity, which can reach several centuries. Their order is not detailed here, and depends essentially on the space available in the timepiece to house the complication.

More particularly, the invention relates to a calendar mechanism 700 for perpetual calendar 100 clock mechanism.

This calendar mechanism 700 is arranged to display the duration of the current month and includes a cam of the month 9, the periphery 90 is accessible to a reader probe 301 of a perpetual calendar mechanism 100 for taking the information of the duration of the current month.

The calendar mechanism 700 and its cam of the months 9 are arranged for their monthly update at each change of current month by such a perpetual calendar mechanism 100.

According to the invention, the cam of the month 9 is trivialized for a whole number of years each having a February month of 28 days, and the calendar mechanism 700 comprises a 900 leap mechanism.

This leap mechanism 900 is external to the cam of the months 9, and arranged to interpose radially, every four years in February, a first correcting finger 901 between on the one hand the periphery 90 of the cam of the months 9 and on the other hand such a reader 301 probe, to give the latter the information that the current February has 29 days instead of 28.

More particularly, and as shown in the figures, the leap mechanism 900 comprises a four-year cam 91, which controls a four-year lever 92. The movement of this four-year lever 92 is permanently transmitted, directly or indirectly, to the first correcting finger 901.

On the particular embodiments of FIGS. 1 to 6, the four-year lever 92 carries the first correction finger 901.

On the particular embodiment of FIG. 7, the four-year lever 92 is a latch which comprises, opposite the four-year cam 91, a first toothed sector 922, which meshes with a second toothed sector 922 that comprises an arm 923, itself carrying of the first correcting finger 901. More particularly still, as visible in FIG. 7, the four year cam 91 is coaxial with the second toothed sector 922 of the arm 923.

Preferably, the monthly movement of the cam of the months 9 is transmitted, with an appropriate transmission ratio, to the cam four years 91.

In a particular embodiment, and in particular on the particular embodiments of FIGS. 1 to 6, the four-year cam 91 is flat, and the four-year lever 92 is movable in a parallel plane and juxtaposed with that of the cam of the months 9, to cooperate with a reader probe 301. Preferably, the The width of this reader 301 is greater than or equal to the total thickness of the four-year lever 92 and the cam of the months 9 juxtaposed to one another. It will be understood that the operation nevertheless remains possible as soon as the width of the reader probe 301 is sufficient to bear both on the four-year lever 92 and on the cam of the months 9. FIGS. 5 and 6 illustrate a more complex mechanism, in which the width of the reader probe 301 is even greater, so that it can cooperate, simultaneously, with the four-year lever 92 and on the cam of the months 9 and still at least one additional control means.

In a particular embodiment, the cam of the month 9 covers four years each having a month of February of 28 days, and drives directly, or via a report inverter one, the four-year cam 91 in synchronous rotation.

In a particular embodiment, advantageous for its simplicity, its small size and illustrated by the figures, the cam of the month 9 covers a single year.

The comparison of FIGS. 2 and 3 shows that in the inactive position B of the four-year lever 92 in FIG. 5, its end 901 does not oppose the probing, by the probe finger 301, the bottom of the notch of the periphery 90, which corresponds to a month of 28 days, the probe finger 301 can then control the corresponding correction by the jump the number of days required, and the appropriate display. In the active position A of FIG. 2, the end 901 opposes the complete descent of the probe finger 301, which is stopped in a radial position corresponding to a month of 29 days, and triggers the update and the corresponding display.

Note that, if the principle of the invention finds a particularly interesting application for the duration of February, it is applicable, with course the substitution, the four-year cam 91, a cam of different control of the corrective lever, at 30 or 31 days, or at 28 or 29 days, or any combination or sequence of periods of varying durations.

Figs. 5 and 6 illustrate a calendar mechanism 700 for an even more precise perpetual calendar, which can be described as a true perpetual calendar.

First, a first mechanism to manage the quadrisecular years, which have February 29 days. The calendar mechanism 700 then comprises a quadrisecular mechanism 950, external to the cam of the months 9, and which is arranged to interpose, every four hundred years in February, a second correcting finger 951 between the periphery 90 of the cam month 9 and a reader 301 probe to give the latter the information that the current February has 29 days instead of 28.

More particularly, as seen in FIGS. 5 and 6, the quadrisecular mechanism 950 comprises a four hundred year old cam 915 controlling a four hundred year old lever 92400 bearing the second correcting finger 951.

In a higher degree of complication, the calendar mechanism 700 manages secular years, which, although theoretically leap, have a February month of 28 days. For this purpose, the calendar mechanism 700 comprises a secular mechanism 980, external to the cam of the months 9, and which is arranged to disengage the leap mechanism 900, every hundred years in February, by preventing the introduction of the first correcting finger 901 between the periphery 90 of the cam of the months 9 and a probe 301 reader.

[0041] More particularly, this age-old mechanism 980 comprises a hundred year old 9100 cam controlling a one hundred year old lever 9200 arranged to prevent, once every hundred years, the changeover of the four-year-old lever 92. Its position B every hundred years forces the four year lever 92 to remain in its inactive position A, since the hundred year old lever 9200 prevents it from returning to its active position B.

In a variant, the four-year lever 92 comprises a hinge in the vicinity of an eccentric stop whose withdrawal movement is controlled by the secular mechanism 980, when the latter operates, to allow the folding of the lever of four years for its declutching, and which eclipsable stop is the rest of the time in an abutment position that prohibits the folding of the four-year lever 92 and maintains it in the deployed position.

In an even higher degree of complication, more difficult to achieve especially because of the gearing for a very long periodicity control, the calendar mechanism 700 manages the quadrillennial years, which, although theoretically leap, have a month of February 28 days.

More particularly, the calendar mechanism 700 then comprises a quadrimillenary mechanism 990, external to the cam of the month 9, and which is arranged to disengage the leap mechanism 900, every four thousand years in February, by preventing the introduction of the first correcting finger 901 between the periphery 90 of the cam of the months 9 and a reader probe 301.

[0045] More particularly, the four-year mechanism 990 comprises a four-thousand-year-old cam 4000 controlling a four thousand year old lever 92000 arranged to prevent, once every four thousand years, the tilting of the four-year lever 92.

In a variant, the four-year lever 92 has a hinge in the vicinity of an eccentric stop whose withdrawal movement is controlled by the four-year mechanism 990, when the latter operates, to allow the folding of the lever of four years for its declutching, and which eclipsable stop is the rest of the time in an abutment position that prohibits the folding of the four-year lever 92 and maintains it in the deployed position.

The invention also relates to a perpetual calendar 100 clock mechanism comprising such a calendar mechanism 700, and a daily downmeter 300 which comprises a reader 301 measuring probe of the duration of the current month and a mechanism of end-of-month catch-up 600. The reader probe 301 takes the information of the duration of the current month on the perimeter 90 of the cam of the months 9.

According to the invention, the daily down-time mechanism 300 determines the current day of the month, controls the display of the date, and controls, at each change of current month, a movement of the cam of the month 9 for the update the calendar mechanism 700, and at least the leap mechanism 900 which he trains. More particularly, the daily downmixing mechanism 300 also provides the drive, as the case may be, of the quadrisecular mechanism 950, the secular mechanism 980, the quadrillillary mechanism 990.

This perpetual calendar mechanism 100 preferably comprises a corrector mechanism 500 comprising control means accessible to the user for controlling, on the one hand updating the leap mechanism 900 in three actions at most, and on the other hand the update of the cam of months 9 in eleven actions at most, compared to the current display.

More particularly, the daily downmixing mechanism 300 is also arranged to control the updating of the quadrisecular mechanism 950, the secular mechanism 980, the quadrimillenary mechanism 990, and the cams, 915, 9100, 4000 respectively, which comprise these mechanisms.

The invention also relates to a timepiece mechanism 800 comprising a watch movement 200 arranged to control the daily trigger, at the time of the change of date, an actuating mechanism of such a perpetual calendar mechanism 100, and comprising a display mechanism 400 comprising at least date display means controlled by the calendar mechanism 700.

The invention also relates to a timepiece 1000 comprising such a clock mechanism 800.

Claims (19)

1. Calendar mechanism (700) for a perpetual calendar (100) calendar mechanism, said calendar mechanism (700) being arranged to display the duration of the current month and comprising a cam of the months (9) whose circumference (90) ) is accessible to a reader probe (301) of a perpetual calendar mechanism (100) for taking information of the duration of the current month, wherein said calendar mechanism (700) and said cam of months ( 9) are arranged for their monthly update at each change of current month by a said perpetual calendar mechanism (100), characterized in that said cam of months (9) is trivialized for an integer number of years each comprising a February month of 28 days, and in that said calendar mechanism (700) comprises a leap mechanism (900) external to said cam months (9) and arranged to interpose radially, every four years in February, a first correcting finger (901 ) between the periphery (90) of said cam months (9) and a said probe reader (301) to give the latter the information that the current February has 29 days instead of 28. 2. calendar mechanism (700) according to claim 1, characterized in that said leap mechanism (900) comprises a four-year cam (91) controlling a four-year lever (92) whose movement is permanently transmitted, directly or indirectly, to said first correcting finger (901). 3. Calendar mechanism (700) according to claim 2, characterized in that said four-year lever (92) carries said first correcting finger (901). 4. Calendar mechanism (700) according to claim 2, characterized in that said four-year lever (92) is a rocker having, opposite said four-year cam (91), a first toothed sector (922 ) which meshes with a second toothed sector (922) that comprises an arm (923) bearing said first correction finger (901). 5. Calendar mechanism (700) according to claim 4, characterized in that said four-year cam (91) is coaxial with said second toothed sector (922) of said arm (923). 6. Calendar mechanism (700) according to one of claims 2 to 5, characterized in that the monthly movement of said cam months (9) is transmitted, with a suitable transmission ratio, to said cam four years ( 91). 7. Calendar mechanism (700) according to one of claims 2 to 6, characterized in that said four-year cam (91) is flat, and in that said four-year lever (92) is movable in a plane parallel and juxtaposed to that of said cam months (9) to cooperate with a reader probe (301) whose width is greater than or equal to the total thickness of said four-year lever (92) and said cam months ( 9) juxtaposed to each other. 8. Calendar mechanism (700) according to one of claims 2 to 7, characterized in that said cam months (9) covers four years each having a month of February of 28 days, and leads directly, or via an inverter of a report, said four year cam (91) in synchronous rotation. 9. Calendar mechanism (700) according to one of claims 1 to 7, characterized in that said cam months (9) covers a single year. 10. Calendar mechanism (700) according to one of claims 1 to 9, characterized in that said calendar mechanism (700) comprises a quadrisecular mechanism (950) external to said cam months (9) and arranged to interpose, every four hundred years in February, a second correcting finger (951) between the periphery (90) of said cam of the months (9) and a said probe reader (301) to give the latter the information that the month from February running to 29 days instead of 28. Calendar mechanism (700) according to claim 10, characterized in that said quadrisecular mechanism (950) comprises a four hundred year old cam (915) controlling a four hundred year old lever (92400) carrying said second correcting finger (951). ). 12. Calendar mechanism (700) according to one of claims 1 to 11, characterized in that said calendar mechanism (700) comprises a secular mechanism (980) external to said cam months (9) and arranged to disengage said leap mechanism (900), every hundred years in February, by preventing the introduction of said first correcting finger (901) between the periphery (90) of said cam months (9) and a said probe reader (301). 13. Calendar mechanism (700) according to claims 2 and 12, characterized in that said secular mechanism (980) comprises a one hundred year old cam (9100) controlling a lever of one hundred years (9200) arranged to prevent, once all the hundred years, the changeover of the four-year lever (92). 14. Calendar mechanism (700) according to one of claims 9 to 11, characterized in that said calendar mechanism (700) comprises a quadrimillenary mechanism (990) external to said cam months (9) and arranged to disengage said leap mechanism (900), every four thousand years in February, preventing the introduction of said first correction finger (901) between the periphery (90) of said cam months (9) and a said probe reader (301) . The calendar mechanism (700) according to claims 2 and 12, characterized in that said four-year mechanism (990) comprises a four-thousand-year-old cam (4000) controlling a four-thousand-year-old lever (92000) arranged to prevent a every four thousand years, the tilting of the four-year lever (92). 16. Perpetual perpetual calendar (100) mechanism comprising a calendar mechanism (700) according to one of claims 1 to 15 and a daily downward mechanism (300) which comprises a reader probe (301) for measuring the duration of the month. in progress and an end-of-month catch-up mechanism (600), said reader probe (301) taking information of the duration of the current month on said periphery (90) of said cam of the months (9), characterized in that said daily downward mechanism (300) determines the current day of the month, controls the display of the date, and controls, at each change of current month, a movement of said cam of the months (9) for the update of said mechanism of calendar (700), and said leap mechanism (900) which he trains. 17. Perpetual calendar mechanism (100) according to claim 16, characterized in that it comprises a corrector mechanism (500) comprising control means accessible to the user to control, firstly the update of said mechanism leap (900) in three actions at most, and secondly the update of said cam months (9) in eleven actions at most, compared to the current display. 18. Watch mechanism (800) comprising a clockwork movement (200) arranged to control the daily trigger, at the time of the change of date, of an actuating mechanism of a perpetual calendar mechanism (100) according to claim 16 or 17, and comprising a display mechanism (400) comprising at least date display means controlled by said calendar mechanism (700). 19. Timepiece (1000) comprising a timepiece mechanism (800) according to claim 18.